Biochar physicochemical properties: pyrolysis temperature and feedstock kind effects

Tomczyk, Agnieszka; Sokołowska, Z.; Boguta, Patrycja

doi:10.1007/s11157-020-09523-3

Cited by 1,187 publications

(422 citation statements)

References 188 publications

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“…Additionally, it was confirmed that there were hydrophilic functional groups on the surface and pores of biochar with a high affinity for water; biochar application was shown to increase soil water retention more in a sandy soil than a loamy soil or a clay soil (Mandal et al 2020). Biochar also showed a positive impact on surface area of soil (Anawar et al 2015), which varied with biochar types (Tomczyk et al 2020). For example, biochar (10%)-amended soil had 3 times higher surface area than untreatedd soil (Tomczyk et al 2019).…”

Section: Physical Propertiesmentioning

confidence: 95%

“…However, in a field study, application of a paddy straw-derived biochar (biochar pH was 10.50) to a sandy soil (soil pH 5.24) increased the pH of the soil by 4.5 units compared to the control (El-Naggar et al 2018b). Moreover, a high dose (50 and 100 t ha −1 ) of biochar (pH 9.40) increased the pH of an Alfisol and, consequently, reduced exchangeable Al concentration in the soil (Tomczyk et al 2020). observed that application of biochar (10, 20, 40, and 60 t ha −1 ) had no impact on soil pH in a semi-arid region, which was consistent with the results reported by Werner et al (2018) who found that the pH of a sandy loam soil was not changed with addition of biochar.…”

Section: Chemical Propertiesmentioning

confidence: 99%

“…Biochars derived from manure-and biosolid-based feedstock materials generally contain higher levels of N and P than those derived from wood-and straw-based feedstock materials (El-Naggar et al 2019a;Purakayastha et al 2019). While the N content decreases with increasing pyrolytic temperature through gaseous emission (Leng et al 2020), the P and K contents increase due to an increase in ash content (Christel et al 2016;Tomczyk et al 2020;Wang et al 2013). As a nutrient sink, biochar can retain nutrients, thereby reducing their losses through leaching and gaseous emission.…”

Section: Introductionmentioning

confidence: 99%

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Biochar and its importance on nutrient dynamics in soil and plant

Hossain

Bahar

Sarkar

et al. 2020

Biochar

290

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Biochar, an environmentally friendly soil conditioner, is produced using several thermochemical processes. It has unique characteristics like high surface area, porosity, and surface charges. This paper reviews the fertilizer value of biochar, and its effects on soil properties, and nutrient use efficiency of crops. Biochar serves as an important source of plant nutrients, especially nitrogen in biochar produced from manures and wastes at low temperature (≤ 400 °C). The phosphorus, potassium, and other nutrient contents are higher in manure/waste biochars than those in crop residues and woody biochars. The nutrient contents and pH of biochar are positively correlated with pyrolysis temperature, except for nitrogen content. Biochar improves the nutrient retention capacity of soil, which depends on porosity and surface charge of biochar. Biochar increases nitrogen retention in soil by reducing leaching and gaseous loss, and also increases phosphorus availability by decreasing the leaching process in soil. However, for potassium and other nutrients, biochar shows inconsistent (positive and negative) impacts on soil. After addition of biochar, porosity, aggregate stability, and amount of water held in soil increase and bulk density decreases. Mostly, biochar increases soil pH and, thus, influences nutrient availability for plants. Biochar also alters soil biological properties by increasing microbial populations, enzyme activity, soil respiration, and microbial biomass. Finally, nutrient use efficiency and nutrient uptake improve with the application of biochar to soil. Thus, biochar can be a potential nutrient reservoir for plants and a good amendment to improve soil properties.

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Section: Physical Propertiesmentioning

confidence: 95%

Section: Chemical Propertiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Biochar and its importance on nutrient dynamics in soil and plant

Hossain

Bahar

Sarkar

et al. 2020

Biochar

290

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“…Recently, biochar (BC) has attracted increasing interest as far as its utilization as filler for polymer-based composites, either thermoplastics or thermosets, is concerned [19,20]. BC is usually obtained from the pyrolysis of agricultural and forestry wastes [21], and its structure can be tuned depending on the pyrolysis conditions; in particular, by adjusting the temperature and the oxygen flow, the degree of internal porosity and the presence of different functional groups anchored to the surface can be tailored [22]. The interest towards BC lies in its intriguing properties, such as high chemical and thermal stability, great electric properties, and very large surface area [23], combined with its cost effectiveness and low environmental impact [24].…”

Section: Introductionmentioning

confidence: 99%

Poly(lactic Acid)–Biochar Biocomposites: Effect of Processing and Filler Content on Rheological, Thermal, and Mechanical Properties

2020

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Biocomposites based on poly(lactic acid) (PLA) and biochar (BC) particles derived from spent ground coffee were prepared using two different processing routes, namely melt mixing and solvent casting. The formulated biocomposites were characterized through rheological, thermal, and mechanical analyses, aiming at evaluating the effects of the filler content and of the processing method on their final properties. The rheological characterization demonstrated the effectiveness of both exploited strategies in achieving a good level of filler dispersion within the matrix, notwithstanding the occurrence of a remarkable decrease of the PLA molar mass during the processing at high temperature. Nevertheless, significant alterations of the PLA rheological behavior were observed in the composites obtained by melt mixing. Differential scanning calorimetry (DSC) measurements indicated a remarkable influence of the processing method on the thermal behavior of biocomposites. More specifically, melt mixing caused the appearance of two melting peaks, though the structure of the materials remained almost amorphous; conversely, a significant increase of the crystalline phase content was observed for solvent cast biocomposites containing low amounts of filler that acted as nucleating agents. Finally, thermogravimetric analyses suggested a catalytic effect of BC particles on the degradation of PLA; its biocomposites showed decreased thermal stability as compared with the neat PLA matrix.

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“…High residence time also affects the quality and amount of biofuel obtained (Tippayawong et al, 2008). In slow pyrolysis, the major by-product obtained is biochar (Tomczyk et al, 2020). The slow pyrolysis process takes more time (up to an hour) for completion as compared to flash and fast pyrolysis.…”

Section: Introductionmentioning

confidence: 99%

Slow Catalytic Pyrolysis of <i>Saccharum munja</i> using Bio-genically Synthesized Nickel Ferrite Nanoparticles for the Production of high yield Biofuel

Din

Javed

Hussain

et al. 2020

EUROPEAN J SUSTAINAB DEV

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In this study, the slow pyrolysis has been performed in a fixed bed reactor using Saccharum munja (munj) as raw biomass material and bio-genically synthesized nickel ferrite nanoparticles (NF-NPs) as a catalyst at an optimum temperature of 450 o C. In the absence of any catalyst, the obtained yield of bio-oil was 43.3 %. The maximum yield of bio-oil (72 %) was obtained with 0.4 g of NF-NPs. With 0.2g of ZSM-5, the obtained bio-oil yield was 44.5 %. The characterization of NF-NPs was studied by using UV-VIS analysis and Fourier Transform Infrared (FT-IR) spectroscopy. The characterization of Bio-char was done by using FT-IR spectroscopy.

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Biochar physicochemical properties: pyrolysis temperature and feedstock kind effects

Cited by 1,187 publications

References 188 publications

Biochar and its importance on nutrient dynamics in soil and plant

Biochar and its importance on nutrient dynamics in soil and plant

Poly(lactic Acid)–Biochar Biocomposites: Effect of Processing and Filler Content on Rheological, Thermal, and Mechanical Properties

Slow Catalytic Pyrolysis of <i>Saccharum munja</i> using Bio-genically Synthesized Nickel Ferrite Nanoparticles for the Production of high yield Biofuel

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